Collisional and Rotational Disruption of Asteroids

TL;DR

This paper reviews how collisions and rotational forces cause asteroid disruptions, revealing insights into their internal structures, shapes, and the formation of binary systems, based on recent modeling and observational data.

Contribution

It provides a comprehensive overview of recent advances in modeling asteroid disruption mechanisms, highlighting their roles in shaping asteroid properties and populations.

Findings

Collisional models reveal asteroid internal structures.

Rotational disruption explains binary asteroid formation.

Space mission data shows diverse asteroid morphologies.

Abstract

Asteroids are leftover pieces from the era of planet formation that help us understand conditions in the early Solar System. Unlike larger planetary bodies that were subject to global thermal modification during and subsequent to their formation, these small bodies have kept at least some unmodified primordial material from the solar nebula. However, the structural properties of asteroids have been modified considerably since their formation. Thus, we can find among them a great variety of physical configurations and dynamical histories. In fact, with only a few possible exceptions, all asteroids have been modified or completely disrupted many times during the age of the Solar System. This picture is supported by data from space mission encounters with asteroids that show much diversity of shape, bulk density, surface morphology, and other features. Moreover, the gravitational attraction of these bodies is so small that some physical processes occur in a manner far removed from our common experience on Earth. Thus, each visit to a small body has generated as many questions as it has answered. In this review we discuss the current state of research into asteroid disruption processes, focusing on collisional and rotational mechanisms. We find that recent advances in modeling catastrophic disruption by collisions have provided important insights into asteroid internal structures and a deeper understanding of asteroid families. Rotational disruption, by tidal encounters or thermal effects, is responsible for altering many smaller asteroids, and is at the origin of many binary asteroids and oddly shaped bodies.